Explore lunar phases as viewed from Earth using a golf ball and an ultraviolet light. With the student's head representing Earth, students hold and move the golf ball to demonstrate the cause of the Moon's phases in their correct order. Related Next...(View More) Generation Science Standards (NGSS) are listed.(View Less)

This is an online lesson associated with activities during Solar Week, a twice-yearly event in March and October during which classrooms are able to interact with scientists studying the Sun. Outside of Solar Week, information, activities, and...(View More) resources are archived and available online at any time. This is an activity about measurements of solar activity. Learners will observe an image of the Sun and sketch major features, plot data to begin to recognize patterns of solar activity, look for long-term patterns in graphed data, compare X-ray and visible light images of the Sun to find solar features common to both sets of images, and make a prediction of what the Sun will look like in a visible light image after observing an X-ray image taken on the same day. This activity is scheduled to occur during Monday of Solar Week.(View Less)

This is an activity associated with activities during Solar Week, a twice-yearly event in March and October during which classrooms are able to interact with scientists studying the Sun. Outside of Solar Week, information, activities, and resources...(View More) are archived and available online at any time. Learners will use SOHO spacecraft images of a coronal mass ejection and tracing paper to measure and then calculate the speed of the coronal mass ejection. This activity is scheduled to occur during Wednesday of Solar Week.(View Less)

In this lesson, learners will construct a 3D scale model of one of the MMS satellites. After, they will calculate the octagonal area of the top and bottom of the satellites, given the measurements of the satellite. Then, learners will compare the...(View More) octagonal cross-section area of the satellites with the circular cross-section area of the launch vehicle to determine if the eight-sided spacecraft will fit the circular rocket hull. This is lesson one of the MMS Mission Educator's Instructional Guide, which uses examples from the MMS Mission to introduce mathematics (focusing on geometry) in a real-world context. The lessons use the 5E instructional cycle. Note: MMS launched March 12, 2015. For the latest science and news, visit the MMS Mission Website under Related & Supplemental Resources (right side of this page).(View Less)

This is the culminating lesson in the MMS Mission Educator's Instructional Guide. Learners will choose and complete three activities about the MMS mission. Activity formats can include creating videos, composing songs, developing written materials,...(View More) constructing models, investigating current events, utilizing mathematics to explain concepts, and more. Depending on the project(s) chosen by a student, the activity may require student access to internet accessible computers. The MMS Mission Educator's Instructional Guide uses examples from the mission to introduce mathematics (focusing on geometry) in a real-world context. The lessons use the 5E instructional cycle. Note: MMS launched March 12, 2015. For the latest science and news, visit the MMS Mission Website under Related & Supplemental Resources (right side of this page).(View Less)

In this lesson, learners will research facts about Atlas V rockets, which launched the MMS satellites. After, they will compute the speed of the launch rocket, given a data chart of time vs. distance from lift-off. Then, they will write a report...(View More) synthesizing their researched information. This lesson requires student access to internet accessible computers. This is lesson two of the MMS Mission Educator's Instructional Guide, which uses examples from the mission to introduce mathematics (focusing on geometry) in a real-world context. The lessons use the 5E instructional cycle. Note: MMS launched March 12, 2015. For the latest science and news, visit the MMS Mission Website under Related & Supplemental Resources (right side of this page).(View Less)

In this activity, teams of learners will model how scientists and engineers design and build spacecraft to collect, store, and transmit data to Earth. Teams will design a system to store and transmit topographic data of the Moon and then analyze...(View More) that data and compare it to data collected by the Lunar Reconnaissance Orbiter.(View Less)

Students are introduced to planetary rocks, soils, and surfaces using images of the lunar samples collected by Apollo astronauts. Examining those images and participating in related activities will lead students to a deeper understanding of the...(View More) Moon, Earth and our Solar System. The 27-page student guide contains background information, images, instructions, questions and activities. The lesson models scientific inquiry using the 5E instructional model and also includes a teacher’s guide, an alignment to Next Generation Science Standards (NGSS), and connections to Common Core English Language standards.(View Less)

This is a lesson about the size and scale of planets in the solar system. Learners will kinesthetically model the order of the planets outward from the sun. Then they will use a string and beads to create a model to represent the relative distances...(View More) between the planets. Finally they will explore another model (using a beach ball for the sun) to discuss relative size of the planets to the sun. The lesson uses the 5E instructional model and includes teacher training, pacing guides, essential questions, a black-line master science notebook, a student presentation booklet, supplemental materials, and vocabulary for both students and teachers. This is lesson 1 of the Mars Rover Celebration Unit, a six week long curriculum.(View Less)